Method and apparatus for personal skin treatment

ABSTRACT

Disclosed is a skin treatment device for personal use. The device includes an optical radiation providing module operating in pulsed or continuous operation mode, a mechanism for continuously displacing the device across the skin, and a device displacement speed monitoring arrangement. When the device is applied to skin, the optical pulses repetition rate establishes the power of the optical radiation as a function of the device displacement speed. The device a hair removal mechanism configured to mechanically remove hair from the treated segment of the skin.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is being filed under 35 U.S.C 371 as a national patentapplication based on International Application Number PCT/IL2009/000817filed on Aug. 20, 2009 which application claims priority to U.S.Provisional Application for Patents 61/098,774 filed on Sep. 21, 2008and 61/180,901 filed on May 25, 2009, all of which are herebyincorporated by reference.

TECHNOLOGY FIELD

The present method and apparatus relate in general to the field of skintreatment and in particular to hair removal.

BACKGROUND

External appearance is important to practically every person. In recentyears, methods and apparatuses have been developed for differentcosmetic and dermatological treatments. Among these are hair removal,treatment of vascular lesions, wrinkle removal, skin rejuvenation andothers. In some of these treatments, the skin surface is illuminated toheat deeper skin or tissue volumes to a sufficiently high temperature asto achieve a desired effect, which is typically in the range of 38-60degrees Celsius. The effect may be weakening of the hair shaft or evenhair follicle or root destruction.

Another desired effect may be hair re-growth retardation, which istypically achieved by illumination of an earlier depilated skin surfaceby laser, LED, Xenon lamp, Intense Pulsed Light (IPL), or incandescentlamp radiation, generally termed optical radiation. The opticalradiation may have a single wavelength for example, lasers, or severalwavelengths, or a broad band spectrum. The wavelengths are selected tobe optimal for the color of the contrasted component of the treated skinsegment, and are typically in the range of 400 to 1800 nm. The opticalradiation, usually flashing or pulsed light, is applied to the skin withthe help of an applicator having an aperture of a given dimension. Inorder to “cover” the entire skin surface, the aperture has to be movedfrom place to place, in a relatively accurate fashion on a step equal toat least one aperture dimension, so that no areas of the skin will bemissed or treated twice. In order to avoid this, the individual visuallytracks applicator location. The light pulses inevitably reach his/hereyes, disturb the individual, and affect the applicator locationtracking and hair removal process. These devices achieve the desiredeffect only if a certain energy density is applied to the skin tissue.If the device is moved too quickly or too slowly across the skin, thedevice may be less efficacious or cause burns, respectively.

Concurrently a number of Radio Frequency (RF) to skin application basedmethods for treatment of deeper skin or tissue layers have beendeveloped. In these methods, electrodes are applied to the skin and anRF voltage in pulse or continuous waveform (CW) is applied across theelectrodes. The properties of the RF voltage are selected to generate RFinduced current in a volume or layer of tissue to be treated. Thecurrent heats the tissue to the required temperature, which is typicallyin the range of 38-60 degrees Celsius. The temperature destroys orinjures the hair follicle or root and delays further hair growth.

Equipment that combines light and RF treatment also exists. Usually thisequipment is configured to illuminate a defined segment of a subjectskin generally similar or equal to the surface of the aperture throughwhich optical radiation is directed to the skin segment. The electrodesare typically located proximal to the periphery of the aperture and theRF typically may heat deeper tissue layers than those heated by lightthus destroying/injuring hair bulbs and/or hair follicle. There is adelicate relation between the amount of RF energy and optical radiationapplied to the same skin segment. Exceeding the optimal proportionbetween them leads to skin burns, whereas application of lower thanoptimal proportion RF energy and optical radiation does not bring thedesired treatment results.

There is a need on the market for a small size, low cost, and safe touse apparatus that may be operated by the user enabling him/her to

-   -   i) avoid skin burns or non sufficient skin treatment results.    -   ii) avoid tediously looking at the treated area, during the        course of treatment.

BRIEF SUMMARY

A skin treatment device for personal use for skin treatment and hairremoval. The device includes an optical radiation providing moduleoperating in pulsed or continuous operation mode, a hair removalmechanism, and a mechanism for continuously displacing the device acrossthe skin. The hair removal mechanism may be a mechanical device and themechanism for continuously displacing the device across the skin may bean optional mechanism. The user applies the device to the skin, operatesthe hair removal mechanism and optical radiation module and displacesthe device manually or with the help of a built-in displacementmechanism across the skin segment to be treated. An optionaldisplacement speed monitoring arrangement monitors the displacementspeed and establishes the optical power as a function of the devicedisplacement speed.

BRIEF LIST OF DRAWINGS

The apparatus and the method are particularly pointed out and distinctlyclaimed in the concluding portion of the specification. The apparatusand the method, however, both as to organization and method ofoperation, may best be understood by reference to the following detaileddescription when read with the accompanying drawings, in which likereference characters refer to the same parts throughout the differentviews. The drawings are not necessarily to scale, emphasis instead beingplaced upon illustrating the principles of the method.

FIG. 1 is a schematic illustration of an exemplary embodiment of theapparatus for personal use for hair removal.

FIG. 2 is a schematic illustration of an exemplary embodiment of theinfrastructure assembly of the applicator or device for personal use forhair removal.

FIG. 3 is a schematic illustration of an exemplary embodiment of theinfrastructure assembly shown without the hair removal mechanism.

FIG. 4 is a schematic illustration of an exemplary embodiment of thereflector of the optical radiation providing module and its coolingmethod.

FIG. 5A is a schematic illustration of an exemplary embodiment of thedevice displacement mechanism.

FIG. 5B is a schematic illustration of another exemplary embodiment ofthe device displacement mechanism.

FIG. 5C is a schematic illustration of an additional exemplaryembodiment of the device displacement mechanism.

FIG. 6 is a schematic illustration of an exemplary embodiment of thedevice displacement speed sensing mechanism.

FIG. 7 is a schematic illustration of an exemplary embodiment of theelectrodes of the device for personal use for hair removal.

FIG. 8 is a schematic illustration of an exemplary disposable andexchangeable skin rejuvenation device for use with the presentapparatus.

FIG. 9 is a schematic illustration of another exemplary method of skintreatment using the present device and apparatus.

FIG. 10 is a schematic illustration of a cross section of anotherexemplary embodiment of the optical radiation providing module and itscooling method.

FIG. 11 is a schematic illustration of an additional exemplaryembodiment of the optical radiation providing module and its coolingmethod.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

In the following detailed description, reference is made to theaccompanying drawings that form a part hereof. This is shown by way ofillustration of different embodiments in which the apparatus and methodmay be practiced. Because components of embodiments of the presentapparatus can be in several different orientations, the directionalterminology is used for purposes of illustration and is in no waylimiting. It is to be understood that other embodiments may be utilized,and structural or logical changes may be made without departing from thescope of the present method and apparatus. The following detaileddescription, therefore, is not to be taken in a limiting sense, and thescope of the present apparatus and method is defined by the appendedclaims.

As used herein, the term “skin treatment” includes hair removal andtreatment of various skin layers such as stratum corneum, dermis,epidermis, skin rejuvenation procedures, wrinkle removal, and suchprocedures as collagen shrinking or destruction.

The term “skin surface” relates to the most external skin layer, whichmay be stratum corneum.

Reference is made to FIG. 1, which is a schematic illustration of anexemplary embodiment of the apparatus for personal skin treatment.Apparatus 100 includes an applicator or device 104 adapted for slidingmovement on a subject skin; a base 108 comprising a controller, powersupply module and a charge storage mechanism, such as a capacitor (notshown), where the power supply may include a transformer with or withoutcurrent rectifier, and an umbilical cord 112 connecting betweenapplicator 104 and base 108. Apparatus 100 may receive power supply froma regular electric supply network receptacle, or from a rechargeable orconventional battery. Applicator or device 104 is designed as aconvenient to hold body (shown as having a transparent envelop)incorporating infrastructure 116, cooling means such as axial fan orblower 120, control circuit 124 controlling the operation of apparatus100, and hair removal mechanism 128 attached to infrastructure frame 116or assembled on a common frame. Hair removal mechanism 128 may be avariety of devices, such as a shaver head, a plucking or tweezingepilator like head, or razor, as a few non-limiting examples. Head 128may be a detachable head or removeable. For safety reasons, the electriccontacts for head 128 may be configured to activate the supply ofelectricity to the hair removal mechanism only when it is properlyinserted in the appropriate location. In an additional embodiment, thehair removal mechanism may be replaced by a skin rejuvenation head (FIG.8).

At least one visual status indicator 132, such as an LED, may beincluded on the device for informing or signifying to a user theoperational status of the apparatus and/or skin treatment processparameter, and/or that a mechanism is attached to device 104, etc. Atleast one optional audio status indicator 136 such as a buzzer signalingto the user the status of skin treatment process parameters is alsoattached to device 104 or located in base 108.

FIG. 2 is a schematic illustration of an exemplary embodiment of theinfrastructure assembly of the applicator or device for personal skintreatment. Mounted on the infrastructure 116 is an optical radiationproviding module 200, a mechanism or arrangement shown in FIGS. 5A-5Cfor continuously displacing device 104 across the skin, a displacementspeed monitoring mechanism (FIG. 5A), and a safety switch (FIG. 3)mounted on the infrastructure frame 116 (FIG. 1) and activated by theradiation providing module 200 (FIG. 2). Hair removal mechanism 128,operatively configured to mechanically remove hair from the treated ortarget segment of the skin, is attached to infrastructure frame 116.Optionally, a pair of electrodes 220 may be attached to infrastructureframe 116.

FIG. 3 is a schematic illustration of an exemplary embodiment of theinfrastructure frame 116 assembly shown without the hair removalmechanism 128 (FIG. 1). It illustrates a safety switch 300 mounted oninfrastructure frame 116 and device 104 displacement direction sensor528 shown in FIG. 5A. Insertion of radiation providing module 200 (FIG.2), into its location in frame 116 activates safety switch 300. Thisprevents idle or erroneous operation of module 200. For example no highvoltages will be present and “alive” in the electrodes of the applicator104 so that users are not subject to high voltage danger if thedisposable cartridge is removed.

According to some embodiments of the disclosure, an RFID device isconnected to control circuit 124 (FIG. 1). The RFID device is preloadedwith a maximal number of pulses to be emitted before the radiationproviding module 200 has to be replaced and decreases the count withevery emitted pulse. Alternatively, the RFID device is preloaded with atotal energy that may be applied to the skin in a single treatmentbefore the radiation providing module 200 (FIG. 2) has to be replaced.The RFID device may also serve as an additional safety measure, wherethe control circuit 124 prevents the radiation providing module 200 fromemitting pulses if the RFID is not identified, namely the radiationproviding module 200 has not been installed correctly.

In an additional embodiment, a 1024 Bit 1-Wire EEPROM such as DS2431commercially available from Maxim/Dallas Semiconductors, Inc.,Sunnyvale, Calif. 94086 U.S.A. 1-Wire EEPROM operating as a counter canbe assembled on the control printed circuit 124 that among otherscontrols the radiation providing module 200. Similar to the RFID, thecounter may be pre-loaded with the desired information. The same 1-WireEEPROM may function for radiation providing module 200 authenticityidentification.

FIG. 4 is a schematic illustration of an exemplary embodiment of thereflector of the optical radiation-providing module and its coolingmethod. Module 200 is implemented as a disposable cartridge including asource of optical radiation 400, a reflector 404 configured to reflectthe emitted optical radiation to the segment of the skin to be treated,and a dielectric coated protective window 408. Window 408 defines theaperture through which the optical radiation is emitted to the skin. Thesource of optical radiation 400, shown in broken lines, may be anincandescent lamp such as AGAC 4627 high power density Xenon flash lampcommercially available from PerkinElmer Optoelectronics Wenzel-JakschStr. 31 65199 Wiesbaden, Germany or other sources such as, but notnecessarily limited to, an LED, laser diode, solid state laser, a gaslaser, or a Xenon IPL (Intense Pulsed Light) lamp.

Reflector 404 is a prismatic case or body with flat facets and polygonalcross section or a tubular case or body with an optional curvature ofsecond or higher power. It may be a simple round cylinder cross section,a parabolic cross section or any other cross section allowing theoptical radiation to be concentrated and distributed uniformly acrossthe aperture of window 408 through which the optical radiation isemitted to the skin. The dielectric coating of window 408 is selectedsuch as to transmit the relevant sections of optical radiation spectrumto the treated segment of the skin and reflect the other. Reflector 404has openings 412 allowing air passage inside the reflector. Openings 412are located about the apex of reflector 404. The dielectric coatedprotective window 408 located adjacent or attached to the openlongitudinal section of reflector 404 forms, with the reflector 404, anair-conducting channel 420 bound on one side by reflector 404 and on theother side by window 408. A part of the stream of cooling air 424generated by a cooling element such as an axial fan 120 (FIG. 1) enterschannel 420 through openings 412. It is directed into the air-conductingchannel 420 along the source of optical radiation 400 shown in brokenlines and cools it. Butt end openings 428 of reflector 404 terminateair-conducting channel on both of the ends and serve as cooling airexhaust openings. The area of air exhaust openings 428 is at least equalor larger to the area of openings

412 allowing air passage into inner part of reflector 404 and airconducting channel 420. The other part of cooling air stream 424 flowsaround the external section of reflector 404 and cools the outer sectionof reflector 404.

According to some embodiments of the disclosure, as depictedschematically in FIG. 10, the cooling means comprise a rotary blower1000. Blower 1000 blows air shown by arrows 1010 into one side of theoptical radiation providing module 200 (FIG. 2), where the air flows inparallel (along) to the source of optical radiation 400 and thereflector 404 (FIG. 4) and emerges from the opposite side as shown byarrows 1020 of the optical radiation providing module 200.

According to some embodiments of the disclosure, as also depictedschematically in FIG. 10, a second glass window 1030 is installed inparallel to window 408 and part of the cooling air blown by the blower1000 and marked by arrow 1040 flows between the two windows 408 and1030. A slanted lamp electrode 1100, as shown in FIG. 11, may beinstalled on the air intake side of the optical radiation source 400, toenhance air flow in the direction of the windows. Arrows 1130schematically illustrate the cooling air flow inside and outsidereflector 404 and between the widows 408 and 1030. Reflector 404 isshown in FIG. 11 as a prismatic structure.

According to some embodiments of the disclosure, a fan 120, as depictedin FIG. 1, may also be used to cool the air between the two glasswindows. It was experimentally proven that three or more windowsparallel to window 408 with cooling air flow between them provide a goodthermal isolation and the part of the device being in contact with theskin almost does not change its temperature.

According to some embodiments of the disclosure, a thermal sensor 1050,such as a thermistor, or any other type of temperature measuring meansmay be installed on either the inflow or the outflow end of the coolingair, as a safeguard against overheating in case of a malfunction of thecooling means.

Windows 408 and 1030 may be made of pyrex, sapphire, quartz, orspecially treated borosilicate glass. Window 1030 or both windows may becoated with a dielectric coating serving as a filter for reflecting backundesired wave lengths, such as UV and certain IR wavelengths, emittedfrom the optical radiation source 400.

According to some embodiments of the disclosure, as also shown in FIG.11, two reflectors (1110, 1120) may be mounted between the two windows(1030, 408), on both sides thereof, to prevent light scattering outsidethe treatment area.

The architecture of optical radiation providing module 200 and themethod of cooling it allows a compact and effective optical radiationsource to be produced and provide sufficient power for skin treatment.Module 200 may operate in pulsed or continuous operation mode. It isknown that low repetition rate optical radiation or light pulses areannoying to the user who may be constantly visually tracking theapplicator location. In order to ease the user's sensation, the opticalradiation source may emit a number of low power light pulses interleavedbetween high power treatment pulses, increasing the repetition rate ofthe light pulses and alleviating the annoying and eye disturbing effectsof low repetition rate light pulses.

FIG. 5A is a schematic illustration of an exemplary embodiment of thedevice displacement mechanism. It illustrates a bottom view of anexemplary mechanism for continuously displacing device 104 across theskin. The mechanism includes a DC motor 500 of suitable size and powercoupled by means of one or more gears 504 to one or more drive wheels508 or a caterpillar type track. The user attaches device 104 to theskin 512 (FIG. 5B) and applies minimal force preventing the device fromfalling of the skin. Device 104 may have additional auxiliary wheels 516in any proper amount, as required. Operation of DC motor 500 allowsdisplacing device 104 across skin 512 with variable speed. A wheel orroller 528 of a known diameter is in contact with the skin. The roller528 rotates as the device moves. Measuring the rotation speed of roller528 makes it possible to determine the device displacement speed bymethods known to those skilled in the art. Alternatively, one of thewheels 508 or 516 may have a known diameter.

In another exemplary embodiment of the device displacement mechanismshown in FIG. 5B a peristaltic piezoceramic motor 516 implemented as acaterpillar type track displaces device 104 across the skin 512 asillustrated by arrow 540. In still an additional exemplary embodiment ofthe device displacement mechanism illustrated in FIG. 5C a belt 520driven by a piezoceramic motor 524 or other type of motor displacesdevice 104 across the skin 512 as shown by arrow 544.

The device displacement mechanisms described above allow displacingdevice 104 with variable speed to be adapted to different skin treatmentconditions. This however requires the ability to sense or monitor, andcorrect the device displacement speed. FIGS. 6A, 6B and 6C, collectivelyreferred to as FIG. 6, is a schematic illustration of an exemplaryembodiment of the device displacement speed and displacement directionsensing arrangement. In FIG. 6A, device 104 (FIGS. 1 and 5) displacementspeed monitoring arrangement 600 may be a rotating wheel 602 or rollerof known diameter being in permanent contact with skin 512. Wheel 602may have an O-ring 604 tensioned on the periphery of wheel 602.Displacement speed monitoring arrangement 600 may be implemented as awheel 602-1 (FIG. 6B) with openings 606 and located between a LED 608with a detector 612 configured to generate pulses when an opening passesbetween them. Alternatively, the wheel may be connected to a speedmeasurement device for example, such as a tachometer being incommunication with control circuit 124. According to the speed-readings,control circuit 124 (FIG. 1) may change the displacement speed of device104. In an alternative embodiment, an arrangement similar to an opticalmouse monitors device 104 displacement speed.

Continuous sensing of the device displacement speed or velocity anddirection of advance, coupled with visual or audio signals informing theuser on the status of the treatment, releases the user from the annoyingtask of constantly tracking the applicator location visually. The userstill has to ascertain that applicator displacement velocity is inaccordance to the desired applicator velocity related to at least theradiation source pulse repeat rate and the active size of the aperture.The visual signal indicator and audio signal indicator provide the userthe information necessary for deciding on the skin treatment status, andthe user is free from memorizing the location of the previously treatedstrip or strips.

Direction displacement sensor may be a wheel 528 (FIG. 5) that may haveasymmetric openings 614 and an LED 608 with a detector 612 configured togenerate pulses when an opening passes between them. Alternatively, oneof the wheels 508 or 516 may have asymmetric openings. Depending on thedisplacement direction the pulses caused by modulation of LED radiationby the openings 612 will have a different rise time, indicating on thedisplacement direction. When treatment of the skin segment is completedthe operator changes the displacement direction of the applicator.

FIG. 7 is a schematic illustration of an exemplary embodiment of theelectrodes of the hair removal device for personal use. Skin treatmentdevice 104 optionally includes a pair of optionally detachableelectrodes 220 (FIG. 2) operatively configured to apply RF energy to asegment of the skin. RF electrodes 220 have an elongated body arrangedalong at least one side of protective window or aperture 408 (FIG. 4).RF electrodes 220 are suspended on springs 700 with respect toinfrastructure frame 116. Alternatively, electrodes 220 may comprisesolid metal strips 710 attached to the external side of the opticalradiation providing module 200 housing. Metal coating deposited onsuitable, maybe even plastic, surfaces of module 200 may also serve aselectrodes 220. During skin treatment RF electrodes 220 are in permanentcontact with skin and accurately follow the skin topography. RFelectrodes 220 or 710 may have a bare metal surface and be in conductivecoupling with the skin, or may be dielectric coated electrodes and be incapacitive coupling with the skin.

FIG. 8 illustrates an exemplary disposable and exchangeable skinrejuvenation device for use with the present apparatus. Device 800 maybe mounted instead of hair removal mechanism 128. Device 800 is acylindrical or other three-dimensional shape carrier 802 on the surfaceof which are dome shaped conductive elements 804 configured such thatdomes 804 protrude from external surface 812 of the carrier 802. Carrier802 may be produced by stretching a flexible substrate over a carcass.This may be a solid cylinder or a squirrel cage type structure. Sides816 of carrier 802 may bear contact strips 820 through which RF voltagecan be supplied to domes 804. Such configuration of the carrier allowsapplying and translating it over relatively large segments of the skin.In the context of the present disclosure, “large segment of skin”signifies a segment of skin dimensions which exceed the dimensions ofthe surface of the carrier, or circumference of the surface of thecontact electrode or electrodes carrier. Carrier 802 has a rotationalsymmetry and can be easily repositioned for treatment of a neighboringskin segment by rolling it on the skin, thus providing a reasonable timefor thermal relaxation of the skin segment treated earlier, and returnedback to the same skin segment treated previously. The repositioning ofthe carrier does not leave segments or patches of the skin that were nottreated and eliminates the residual patchwork type skin pattern. Thistype of skin treatment actually represents a continuous skin surfacetreatment process. Carrier 802 may be a reusable or disposable part.

FIG. 9 is a schematic illustration of an exemplary method of skintreatment using the present device and apparatus. For skin treatment,device 104 is applied to a segment of skin 900 to be treated, enablingpermanent or at least mostly permanent contact between the RF electrodes220 (FIG. 2) and the skin. Optical radiation providing module 200 isactivated, and the mechanism for continuously displacing the deviceacross the skin displaces device 104 in a desired direction, forexample, along the segment of the skin to be treated. In one embodiment,optical radiation is directed through aperture 408 to irradiate asegment of skin to be treated by a constant optical radiation power,supplied in continuous or pulsed mode, and displacement speed monitoringarrangement 600 (FIG. 6) sets a proper displacement speed. Thedisplacement speed—optical radiation power dependence may be preparedand loaded as a look-up-table (LUT) into control circuit 124. As thetreatment progresses and device 104 advances across the skin, it reachesthe border of the skin segment to be treated. As device 104 reaches theend of the treated or shaved skin segment, the user manually repositionsdevice 104 on the next segment of skin to be treated or on anothernon-treated segment of the skin and sets it for displacement into thesame or opposite direction. The danger of causing skin burns by treatingthe same segment of skin twice is reduced, since there is some time forthe skin to cool down between successive skin treatments by device 104.Optical radiation retards future hair growth on the treated segment ofthe skin by heating hair follicle. RF energy applied to the same skinsegment heats deeper skin layers where hair bulbs and follicles arelocated, and the heat generated by the RF energy destroys them,enhancing the hair removal process performed by the optical radiation.

In an additional exemplary method of skin treatment using the presentdevice and apparatus, the user applies the skin treatment device 104 toa skin segment from which hair has to be removed. The hair is removedfrom the skin segment by mechanical means, for example by shaving it orplucking it. Following mechanical hair removal, optical radiation ofproper power and wavelength is applied to the same segment of skin thatwas treated. Optionally, RF energy may be applied to the same segment ofskin. Application of optical radiation and RF energy retards furtherhair growth and removes hair residuals left after mechanical hairremoval from the treated skin segment. Similar to the earlier disclosedmethod the device treating the skin segment displaces itselfautomatically from a treated skin segment to another untreated skinsegment.

A number of embodiments have been described. Nevertheless, it will beunderstood that various modifications may be made without departing fromthe spirit and scope of the method. Accordingly, other embodiments arewithin the scope of the following claims:

What is claimed is:
 1. A skin treatment device for personal use, saiddevice comprising: a means for cooling operatively adapted to create airflow within the device; an optical radiation providing module, whereinthe optical radiation providing module comprises: a source of opticalradiation; a reflector configured to reflect the emitted opticalradiation through at least one dielectric coated protective window,wherein the at least one dielectric coated protective window is locatedadjacent an open longitudinal section of the reflector and forms withthe reflector an air-conducting channel bound on one side by thereflector and on the other side by the dielectric coated protectivewindow, wherein the reflector is an elongated tubular or prismatic casehaving a curved or polygonal cross section, wherein the reflector isconfigured to have air passage openings that extend longitudinally downthe apex of the reflector located about the apex of the reflector andalong the longitudinal axis of said reflector and to allow air flow fromthe cooling means inside the reflector in a direction substantiallyperpendicular to the source of optical radiation; air exhaust openingslocated at the open butt ends of the reflector such that air flow fromthe cooling means into the air-conducting channel of the reflectorprovides cooling for the source of optical radiation; and at least oneadditional window positioned substantially parallel to the at least onedielectric coated protective window such that the at least oneadditional window is substantially thermally isolated from the at leastone dielectric coated protective window, wherein air flow from thecooling means directed in between the at least two parallel windowsprovides additional thermal isolation; and a means for continuouslydisplacing the device across a segment of skin such that thedisplacement direction is substantially perpendicular to the directionof the optical radiation reflected through the at least two parallelwindows of the optical radiation providing module, wherein the means forcontinuously displacing monitors the rate of displacement of the deviceand influences the amount of optical radiation emitted by the opticalradiation source.
 2. The optical radiation providing module according toclaim 1, further comprising at least a pair of RF electrodes operativelyconfigured to provide RF current.
 3. The optical radiation providingmodule according to claim 1, wherein the surface of the air exhaustopenings is equal to or greater than the surface of air passage openingsin the reflector.
 4. The skin treatment device according to claim 1,wherein the optical radiation providing module is a disposablecartridge.
 5. The skin treatment device according to claim 1, whereinthe means for cooling are one of a group consisting of a fan and ablower.
 6. The skin treatment device according to claim 1, wherein themeans for cooling is operatively configured to create air flow along thesource of optical radiation.
 7. The skin treatment device according toclaim 1, wherein the means for cooling is operatively configured tocreate air flow between the at least two parallel windows.
 8. The skintreatment device according to claim 1, wherein the source of opticalradiation is one of a group consisting of an incandescent lamp, an LED,a laser diode, a solid state laser, a gas laser and a Xenon IPL lamp. 9.The skin treatment device according to claim 1, wherein the dielectriccoated protective window filters and defines, at least in part, thespectrum of the optical radiation emitted through the at least twowindows.
 10. The skin treatment device according to claim 1, wherein themeans for continuously displacing the device comprises at least one of agroup consisting of a DC motor with a gear, a peristaltic piezoceramicmotor and a caterpillar driven by a piezoceramic motor.
 11. The skintreatment device according to claim 2, wherein the RF electrode is oneof a group consisting of a metal strip and a metal coated nonconductivematerial, and wherein the RF electrode has an elongated body arrangedalong at least one side of the at least one additional window.
 12. Theskin treatment device according to claim 2, wherein the RF electrode isat least one of a group of uncoated or dielectric coated electrodes. 13.A method for cooling an optical radiation providing module and thermallyisolating an optical radiation source in said optical radiationproviding module, said method comprising: forming an firstair-conducting channel by attaching at least one dielectric coatedprotective window to a reflector of an optical radiation providingmodule, wherein the at least one dielectric coated protective window islocated adjacent an open longitudinal section of the reflector, whereinthe air-conducting channel is bound on one side by the reflector and onthe other side by the dielectric coated protective window, wherein thereflector is an elongated tubular or prismatic case having a curved orpolygonal cross section, wherein the reflector is configured to have airpassage openings that extend longitudinally down the apex of thereflector located about the apex of the reflector and along thelongitudinal axis of said reflector; forming a second air-conductingchannel between the at least one dielectric coated protective window andat least one additional window positioned substantially parallel to theat least one dielectric coated protective window; directing air flow, bya means for cooling operatively adapted to create air flow, into and outof the air-conducting channels.
 14. A skin treatment device for personaluse, said device comprising: a means for cooling operatively adapted tocreate air flow within the device; an optical radiation providing modulecapable of operating in pulsed or continuous mode, wherein when theradiation providing module operates in pulse mode it radiates a numberof low power pulses interleaved between high power treatment pulses,wherein the optical radiation providing module comprises: a source ofoptical radiation; a reflector configured to reflect the emitted opticalradiation through at least one dielectric coated protective window,wherein the at least one dielectric coated protective window is locatedadjacent an open longitudinal section of the reflector and forms withthe reflector an air-conducting channel bound on one side by thereflector and on the other side by the dielectric coated protectivewindow, wherein the reflector is an elongated tubular or prismatic casehaving a curved or polygonal cross section, wherein the reflector isconfigured to have air passage openings located that extendlongitudinally down the apex of the reflector about the apex of thereflector and along the longitudinal axis of said reflector and to allowair flow from the cooling means inside the reflector in a directionsubstantially perpendicular to the source of optical radiation; airexhaust openings located at the open butt ends of the reflector suchthat air flow from the cooling means into the air-conducting channel ofthe reflector provides cooling for the source of optical radiation; andat least one additional window positioned substantially parallel to theat least one dielectric coated protective window such that the at leastone additional window is substantially thermally isolated from the atleast one dielectric coated protective window, wherein air flow from thecooling means directed in between the at least two parallel windowsprovides additional thermal isolation; and a means for continuouslydisplacing the device across a segment of skin such that thedisplacement direction is substantially perpendicular to the directionof the optical radiation reflected through the at least two parallelwindows of the optical radiation providing module, wherein the means forcontinuously displacing monitors the rate of displacement of the deviceand influences the amount of optical radiation emitted by the opticalradiation source.